Electronic governor system and load sensing system

ABSTRACT

An electronic governor system includes a motor, a transmission coupled to the motor, a throttle plate coupled to the transmission, the throttle plate movable to multiple positions between closed and wide-open, wherein power is supplied to the motor to move the throttle pate to a desired position and wherein power is not supplied to the motor to maintain the throttle plate in the desired position.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional Application No.62/081,221, filed Nov. 18, 2014 and claims the benefit of U.S.Provisional Application No. 61/987,350, filed May 1, 2014, both of whichare incorporated herein by reference in their entireties.

BACKGROUND

The present invention relates generally to the field of electronicgovernors, and more particularly to electronic governors for smallengines. A typical electronic governor controls engine speed bycontrolling throttle plate position with a stepper motor.

SUMMARY

One embodiment of the invention relates to an electronic governor systemincluding a motor, a transmission coupled to the motor, a throttle platecoupled to the transmission, the throttle plate movable to multiplepositions between closed and wide-open, wherein power is supplied to themotor to move the throttle pate to a desired position and wherein poweris not supplied to the motor to maintain the throttle plate in thedesired position.

Another embodiment of the invention relates to an electronic governorsystem including a motor, a transmission coupled to the motor, athrottle plate coupled to the transmission, the throttle plate movableto multiple positions between closed and wide-open, an engine speedsensor, and a controller including a feedback control module and anadaptive control module. The feedback control module is configured todetermine an engine speed error based on a comparison of a currentengine speed input signal from the engine speed sensor and a desiredengine speed and provide an engine speed output signal to the motor tocontrol the position of the throttle plate to correct the engine speederror, wherein the engine speed output signal is determined by a controlalgorithm using the engine speed error as an input. The adaptive controlmodule is configured to determine an expected engine speed errorcorrection based on the engine speed output signal provided by thefeedback control module, determine an actual engine speed errorcorrection based on a current engine speed input signal from the enginespeed sensor and a previous engine speed input signal from the enginespeed sensor, determine a correction error based on the expected enginespeed error correction and the actual engine speed correction, andadjust a parameter of the control algorithm of the feedback controlmodule when the correction error is within a predetermined range oroutside of a predetermined range.

Another embodiment of the invention relates to a four-cycle smallinternal combustion engine including an engine speed sensor configuredto detect an engine speed, an electronic governor system configured tochange an engine operating speed in response to a load input, and a loadsensing system configured to determine an engine load based on changesin the detected engine speed and provide the load input to theelectronic governor system based on the determined engine load.

Alternative exemplary embodiments relate to other features andcombinations of features as may be generally recited in the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will become more fully understood from the followingdetailed description, taken in conjunction with the accompanyingdrawings, in which:

FIG. 1 is a perspective view of a portion of an internal combustionengine including an electronic governor system according to an exemplaryembodiment;

FIG. 2 is a schematic representation of an electronic governor systemaccording to an exemplary embodiment;

FIG. 3 is a block diagram of the controller of an electronic governorsystem according to an exemplary embodiment; and

FIG. 4 is a perspective view of a portion of the internal combustionengine of FIG. 1 including the electronic governor system.

FIG. 5 is a perspective view of the internal combustion engine of FIG. 1including the electronic governor system.

FIG. 6 is a schematic representation of a portion of an electronicgovernor system, according to an exemplary embodiment, with anelliptical gear set in a first operating position.

FIG. 7 is a schematic representation of the portion of the electronicgovernor system of FIG. 6 with the elliptical gear set in a secondoperating position.

DETAILED DESCRIPTION

Before turning to the figures, which illustrate the exemplaryembodiments in detail, it should be understood that the application isnot limited to the details or methodology set forth in the descriptionor illustrated in the figures. It should also be understood that theterminology is for the purpose of description only and should not beregarded as limiting.

Referring to FIGS. 1-2 and 4-5, an electronic governor system isillustrated according to an exemplary embodiment. The electronicgovernor system 100 is shown in use on a small engine 105. Theelectronic governor system 100 includes a carburetor 110, a motor 115(e.g., a direct current (“DC”) motor), a transmission 120, a throttleplate 125, a throttle lever 130 and a linkage 135 connecting thethrottle lever to the transmission. In the carburetor 110, fuel is mixedwith air to produce an air/fuel mixture for combustion in one or morecylinders of the engine 105. The throttle plate 125 controls the flow ofthe air/fuel mixture out of the carburetor 110 and in doing so controlsthe speed of the engine 105. As illustrated, the linkage 135 includes alink 140 and a crank arm 145. In some embodiments the electronicgovernor system 100 also includes an encoder 150 that is coupled to themotor 115 and the transmission 120.

The motor assembly (i.e., the motor 115 and the transmission 120) isused to control the position of the throttle plate 125, therebycontrolling the engine speed. The throttle plate 125 is movable betweena closed position and a wide-open position. The position of the throttleplate 125 is adjusted so that the engine speed is maintained at adesired engine speed. The desired engine speed can be a constant or canbe varied by a user or a controller in response to inputs from theengine (e.g., inputs related to engine load, desired output, or otherengine operating conditions or objectives).

The motor 115 is relatively low cost, particularly with respect to thestepper motor typically used in other electronic governor systems. Themotor 115 does not track steps of the motor's rotation like a steppermotor. In some embodiments, the motor 115 is a brushed motor. Thetransmission 120 provides a large reduction ratio (i.e., inputspeed/output speed). For example, the motor 115 may have a top speed of4,000 revolutions per minute (rpm). The transmission 120 may provide areduction so that the output from the transmission turns at 100 rpm(i.e., a 40:1 reduction ratio). This will result in a transmissionoutput speed that is relatively fast as compared to the amount ofrotation necessary to adjust the throttle plate position (e.g., 75 to100 rpm), with the throttle plate's range of motion (i.e., between theclosed position and the wide-open position) being less than a fullrevolution, and produces a relatively large amount of torque. At thisrelatively fast transmission output speed the throttle plate 125 is ableto move from closed to wide open in about 40 milliseconds. As anotherexample, the motor 115 may have an output speed of at about 10,000 rpmand the transmission may provide a gear reduction such that the outputof the transmission is about 60 rpm (i.e. a reduction ratio of about167:1). In some embodiments, the transmission 120 is a series of gearsthat provides a reduction from the input of the motor to the output ofthe transmission. The transmission 120 providing a large reduction ratioproduces an output from the transmission 120 with a relatively largeamount of torque. The output shaft of the transmission 120 only needs torotate a small amount to adjust the throttle plate position within thethrottle plate's range of motion and in doing so is able to produce alot of torque. Another advantage of this large reduction ratio is thatpower only needs to be supplied to the motor 115 when moving the outputshaft of the transmission 120 to the desired position. This positioncorresponds with the desired position of the throttle plate 125. Afterthe output shaft of the transmission 120, and therefore the throttleplate 125, has reached the desired position, the motor 115 is no longerpowered (i.e., the motor 115 is turned off). In this way, power is notneeded to maintain the position of the output shaft of the transmission120 and of the throttle plate 125. The relatively large reduction ratioprovided by the transmission 120 is able to maintain or hold thethrottle plate 125 in position without power being supplied to the motor115 to maintain the desired position of the throttle plate 125. In someembodiments several components of the electronic governor system 100 areincluded within a single housing. For example, the motor 115 and thetransmission 120 could form a single unit. This unit may be combinedwith the controller 155 and its associated circuit board.

As shown in FIG. 1, the linkage 135 connects the output shaft of thetransmission 120 to the throttle lever 130. The throttle lever 130 isconnected to the throttle plate 125, such that the motor 115 drives thetransmission 120 which moves the linkage 135 which moves the throttlelever 130 which moves the throttle plate 125. In this way, powering themotor 115 causes the throttle plate 125 to change position. Though thelinkage 135 is shown as a two-piece linkage, other appropriatemechanisms for connecting the output shaft of the transmission 120 tothe throttle plate 125 may be utilized. For example, the output shaft ofthe transmission 120 could be directly connected to the throttle plate125 or one or more components could be used to connect the output shaftof the transmission 120 to the throttle plate 125. In some embodiments,one or more gears are used to connect the output shaft of thetransmission 120 to the throttle plate 125.

In some embodiments, the encoder 150 is connected to the motor 115 andthe transmission 120 to determine the position of the output shaft ofthe transmission 120. In some embodiments, the encoder 150 is anabsolute encoder and can be used to keep track of the position of theoutput shaft of the transmission 120 and therefore the position of thethrottle plate 125.

As shown in FIG. 2, the electronic governor system 100 includes acontroller 155 that controls the operation of the motor 115. In someembodiments, the controller 155 also controls the operation of othercomponents of the electronic governor system 100 that will be describedin more detail below. These components may include an engine speedsensor 160, a user interface 165, a temperature sensor 170, a currentsensor 175, an ignition system 180, and a rev limiter 185. Differentembodiments of the electronic governor system 100 may include some, noneor all of these additional components.

As shown in FIG. 3, the controller 155 includes a processing circuit190, an input interface 195, and an output interface 200. The processingcircuit 190 includes a processor 205 and memory 210. The processingcircuit 190 and processor 205 are configured to receive inputs frominput interface 195 (e.g., via a wired or wireless communication linkwith other components of the engine and/or electronic governor system)and to provide an output (e.g., a control signal, an actuator output,etc.) via output interface 200 (e.g., via a wired or wirelesscommunication link to the motor 115, other components of the engine,and/or other components of the electronic governor system). Theprocessing circuit 190 can be a circuit containing one or moreprocessing components (e.g., the processor 205) or a group ofdistributed processing components. The processor 205 may be a generalpurpose or specific purpose processor configured to execute computercode or instructions stored in the memory or received from othercomputer readable media (e.g., CD-ROM, network storage, a remote server,etc.). The processing circuit 190 is also shown to include the memory210. Memory 210 may be RAM, hard drive storage, temporary storage,non-volatile memory, flash memory, optical memory, or any other suitablememory for storing software objects and/or computer instructions. Whenthe processor 205 executes instructions stored in the memory 210 forcompleting the various activities described herein, the processor 205generally configures the computer system and more particularly theprocessing circuit 190 to complete such activities. The memory 210 mayinclude database components, object code components, script components,and/or any other type of information structure for supporting thevarious activities described in the present disclosure. For example, thememory 210 may store data regarding the operation of a controller (e.g.,previous setpoints, previous behavior patterns regarding used energy toadjust a current value to a setpoint, etc.). According to an exemplaryembodiment, the memory 210 is communicably connected to the processor205 and includes computer code for executing one or more processesdescribed herein and the processor 205 is configured to execute thecomputer code.

The memory 210 is shown to include a feedback control module 215 and anadaptive control module 220. The memory may include a throttle plateposition module 225 and an engine shutdown module 230. The feedbackcontrol module 215 is the primary logic module configured to provide thefeedback-based control activity of the controller 155. In someembodiments, the feedback control module 215 is aproportional-integral-derivative (PID) control module. In otherembodiments, the feedback control module 215 is a fuzzy logic controlmodule. The feedback control module 215 uses information from the inputinterface 195 (e.g., detected engine speed) to calculate or otherwiseobtain the controlled variable (e.g., throttle plate position). Thefeedback control module 215 may also use information stored in thememory 210 (e.g., previous detected engine speed, desired engine speed,etc.) in calculating or obtaining the controlled variable. The adaptivecontrol module 220 is configured to determine appropriate values ofcontrol parameters (e.g., proportional gain, integral gain, derivativegain, etc.). The adaptive control module 220 may tune control parametersbased on a model identification adaptive control (MIAC) approach oranother adaptive tuning approach or algorithm.

The feedback control module 215 is configured to provide an engine speedcontrol output based an engine speed error determined by a comparison ofa current engine speed input from the engine speed sensor 160 with thedesired engine speed. The output is provided to the motor 115 to adjustthe throttle plate 125 position, thereby controlling the engine speedand correcting any engine speed error so that the detected engine speedand the desired engine speed are the same or substantially the same(e.g., within a predetermined range). The feedback control module canuse different types of feedback control including PID control algorithmsor fuzzy logic control rules. The adaptive control module 220 adjustsone or more parameters (e.g., coefficients, gains, rules, etc.) of thefeedback control module 215 such that the feedback control module learnsthe appropriate operating parameters for a specific engine and endproduct (e.g., lawn mower, snow thrower, generator, pressure washer,etc.). For example, the feedback control module 215 may determine anengine speed error and provide an engine speed output intended tocorrect that error or a portion of the error (e.g., reduce the error byhalf). The adaptive control module 220 determines what an expectedengine speed error correction is based on the output provided by thefeedback control module 215. The adaptive control module 220 alsodetermines an actual engine speed correction based on the current enginespeed input from the engine speed sensor 160 and a previous engine speedinput from the engine speed sensor 160. The adaptive control module 220then is able to determine a correction error based on the expectedengine speed error and the actual engine speed correction. In this way,the adaptive control module 220 is able to determine if the actualengine speed correction is the same as or close to the expected enginespeed error correction (e.g., determine a correction error).

If the actual engine speed correction is not the same (or within apredetermined range acceptable as the same) as the expected engine speedcorrection, the adaptive control module 220 adjusts one or moreparameters of the feedback control module 215. When the actual enginespeed error correction was less than the expected engine errorcorrection the parameter change is such that the subsequent attempt atcorrecting engine speed will be more aggressive. As used herein, moreaggressive means that the position change of the throttle plate withadjusted parameter setting will be greater than at the previousparameter setting and less aggressive means that the position change ofthe throttle plate with adjusted parameter setting will be less than atthe previous parameter setting. For example, in a controller 155 usingPID control the adaptive control module 220 can change one or more ofthe proportional, integral and derivative parameters (e.g., coefficientsor gains) of the feedback control module 215 to achieve the desiredchange in engine speed. The PID control of the feedback control module215 may set forth a control algorithm to determine the motoradjustment—the amount of time voltage is supplied to the motor 115 (theduration or “width” of a voltage pulse). For example, the PID controlalgorithm may use the following equation to determine the motoradjustment where Error is the engine speed error.

${{Motor}\mspace{14mu}{Adjsutment}} = {{P_{i}{Error}} + {D_{i}\frac{d{Error}}{d\; t}} + {I_{i}{\int{Error}}}}$

The adaptive control module 220 may be configured to adjust one or moreof the proportional, integral and derivative parameters in response to acomparison of the actual change in engine speed following a throttleplate position adjustment (e.g., as measured by the engine speed sensor160) with the expected change in engine speed following a throttle plateposition adjustment (e.g., the engine speed error or a portion (e.g.,one half, one third, etc.) of the engine speed error). If the actualchange in engine speed is less than the expected change in engine speed,one or more of the parameters is adjusted to make the motor adjustmentmore aggressive (i.e., provide a voltage pulse of a longer duration). Ifthe actual change in engine speed is greater than the expected change inengine speed, one or more of the parameters is adjusted to make themotor adjustment less aggressive (i.e., provide a voltage pulse of ashorter duration). The comparison of actual change in engine speed tothe expected change in engine speed can be performed at a specific time(e.g., 2-3 engine cycles) after a motor adjustment pulse is sent to themotor 115. In some embodiments, the pulse of the motor adjustment has aduty cycle and the duty cycle of the pulse of the motor adjustment maybe adjusted when the actual change in engine speed is different than theexpected change in engine speed. In some embodiments, the motoradjustment algorithm

In some embodiments using a PID control algorithm there are multipleparameter sets. For example, a first parameter set may be used when thethrottle plate 125 is close or near to the closed position and a secondparameter set may be used when the throttle plate 125 is close or nearto the wide open position. This is helpful because the operatingperformance (e.g., speed) of the engine is not linear with respect tothrottle plate position. When the throttle plate 125 is near the wideopen position, the engine speed is not very responsive to changes in thethrottle plate position and when the throttle plate 125 is near theclosed position, the engine speed is more responsive to changes in thethrottle plate position. Therefore, the parameter set associated withoperation when the throttle plate 125 is near the closed position wouldbe less aggressive than the parameter set that is used when the throttleplate 125 is near the wide open position. Two or more parameter setsbased on the throttle position could be implemented. For example a curvecould be fit so that the parameter sets used change from the closedposition to the wide open position.

The adaptive control module 220 may also be configured to perform acomparison of the expected output (i.e., rotational speed) of the motor115 from a particular duration of applied voltage (voltage pulse) to theback electromotive force (“back-EMF”) actually caused by that particularduration of applied voltage. Back-EMF is caused by the rotation of themotor and can act as a proxy for a motor sensor for detecting therotational speed of the motor. In this way the adaptive control module220 allows the system to learn or adjust to the operationalcharacteristics of a particular engine. Variations among particularengines (e.g., individual DC motors, the end use of the engine, etc.)will result in different duration voltage pulses being necessary to movea throttle plate a specific amount. For example, in one engine a voltagepulse of 10 milliseconds may move the throttle plate 10 degrees, but mayonly move the throttle plate of a second engine 5 degrees. The back-EMFcorrelation performed by the adaptive control module 220 allows thesystem to learn the particular voltage pulse duration needed for aparticular throttle plate position change within the addition of a motorspeed sensor and allows for that correlation to change as engineperformance changes over the life of a particular engine. The back-EMFcomparison can also be used to determine when the throttle plate 125 isat either end of its range of motion (i.e., closed position or wide openposition) because the throttle plate 125 is at a hard stop at either endof its range of motion and the back-EMF should approach zero as themotor is unable to turn. The back-EMF comparison can also be used toidentify variations between the operational characteristics ofindividual motors and a curve establishing a known or desiredrelationship between back-EMF and engine speed (e.g., RPM) and todetermine the operational characteristics that need to be modified(e.g., duration of voltage pulses) to fit a specific motor to the knownback-EMF and engine speed curve.

As shown in FIGS. 6-7, in some embodiments of the electronic governorsystem 100, an elliptical gear set 186 is included between thetransmission 120 and the throttle lever 130 to account for thenon-linearity of engine speed with respect to throttle plate position.The elliptical gear set 186 includes two elliptical gears—a driving gear187 and a driven gear 188. The driving gear 187 has a minor radius 189that is less than a major radius 191. The driving gear 187 is coupled toor a component of the transmission 120. The driven gear 188 is coupledto the throttle plate 125 (e.g., directly or indirectly by one or morelinks or gears). The driven gear 188 has a minor radius 192 that is lessthan a major radius 193. The elliptical gear set 186 is arranged so thatthe driven gear 188 provides a relatively large amount of movement ofthe throttle plate 125 in response to specified amount of movement ofthe driving gear 187 when the throttle plate 125 is near the wide openposition (FIG. 6) and so that the driven gear 188 provides a relativelysmall amount of movement of the throttle plate 125 in response to thesame specified amount of movement of the driving gear 187 when thethrottle plate 125 is near the closed position (FIG. 7). As shown inFIG. 6, when the throttle plate 125 is near the wide open position, themajor radius 191 of the driving gear 187 engages the minor radius 192 ofthe driven gear 188. As shown in FIG. 7, when the throttle plate 125 isnear the closed position, the minor radius 189 of the driving gear 187engages the major radius 193 of the driven gear 188.

In embodiments where the feedback control module 215 uses a fuzzy logiccontrol algorithm to control the output to the motor 115, a list offuzzy logic rules is created to control the operation of the motor 115.These rules allow for non-linear control of the non-linear engineoperation. In some embodiments, the temperature sensor 170 provides thedetected temperature as an input to the fuzzy logic rule set.

In some embodiments the electronic governor system 100 includes atemperature sensor 170. The temperature sensor 170 is configured todetect a temperature (e.g., an ambient temperature, an enginetemperature, or other appropriate temperature). The detected temperatureis provided as an input to the controller 155 and may be utilized as aninput to the various logic modules of the controller 155. As the enginemay operate differently as relatively cold temperatures and relativelyhot temperatures different control parameters (e.g., of the feedbackcontrol module 215 and/or the adaptive control module 220) can be usedwhen the detected temperature is either below or above one or morethresholds (e.g. a hot operating condition threshold and a coldoperating condition threshold).

The memory 210 may also include a throttle plate position module 225.The throttle plate position module 225 is configured to determine theposition of the throttle plate 125 based on tracking the expectedchanges in the throttle plate position from an initial throttle plateposition. The initial throttle plate position is known. For example, thewide open position may be considered to be 90° and the closed positionmay be considered to be 0°. Based on that starting position (e.g., thewide open position), the throttle plate position module 225 calculates acurrent throttle plate position based on the changes to the throttleplate position caused by the motor 115. The product of the voltageapplied to the motor 115 and the amount of time for which that voltageis supplied corresponds to an expected change in the position of thethrottle plate 125. By keeping track of all expected movements of thethrottle plate 125 from the initial known position caused by operationof the motor 115, the throttle plate position module 225 is able totrack the position of the throttle plate 125. Alternatively, an encoder(e.g., the encoder 150) may keep track of the throttle plate position.However, an encoder adds cost that may not be necessary for theelectronic governor system 100 to operate as desired.

The engine 105 includes an ignition system 180. In some embodimentsexcess energy from the ignition system 180 is used to power the motor115 and/or the controller 155. In this way the electronic governorsystem 100 is able to operate without a separate or dedicated powersupply (e.g., a separate battery or the battery used to power anelectric engine starting system). In a magneto or spark ignition systemextra energy in the form of ignition sparks or pulses can be harvestedand stored in a capacitor or other energy storage device (e.g., battery)for use to power the motor 115. Though a spark based ignition system isdiscussed as an example other types of ignition systems are possible.The excess energy of the ignition system may also be sufficient to powerthe motor 115 and/or the controller 155. After the engine 105 isstarted, there is a relatively abundant amount of excess energy that canbe harvested to power the electronic governor system 100. For example,the energy from the two positive pulses or sparks of a four-cyclemagneto ignition system can yield about one amp of current. Other typesof ignition systems also provide waste energy that could be harvested topower the electronic governor system. In a four-cycle magneto ignitionsystem there is a waste spark on the exhaust stroke of the cylinder. Insuch a system, the two positive pulses or sparks and the waste negativepulse or spark could all be harvested. In some embodiments, other powersupplies that do not include a separate or dedicated power supply (e.g.,a separate battery) may be used to power the motor 115 and/or thecontroller 155. Alternative power supplies include an alternator drivenby the engine 105, a thermoelectric power generator that makes use ofwaste heat from the engine 105, a piezoelectric power generator drivenby vibrations of the engine 105 and/or the outdoor power equipmentdriven by the engine 105, a Faraday power generator including a magnetoscillating within a coil driven in sync with the reciprocating movementof the piston of the engine 105. In some embodiments, an energy storagedevice (e.g., a rechargeable battery, a capacitor, etc.) is provided tostore the energy produced by the power supplies described above. In thisway, power is available for the motor 115 and/or the controller 155 whenthe engine 105 is initially started and there is not an immediatelyavailable supply of energy to be harvested from the operating engine105.

A rev limiter 185 may be provided to prevent the engine 105 fromachieving an overspeed condition in which the engine speed exceeds athreshold (e.g., a redline). The rev limiter 185 detects the enginespeed and when the engine speed exceeds the threshold, shorts theignition to prevent the engine from continuing to exceed the speedthreshold. To make the reduction in speed associated with shorting theignition smoother (e.g., less sudden and/or less noisy to the operator),it may be preferable to short a subset of the ignition sparks ratherthan all of the engine sparks. Shorting all of the ignition events(e.g., sparks associated with combustion events) would have an audibleeffect and the engine speed would abruptly drop. Shorting fewer than100% of the ignition events (e.g., every second, third, fourth, etc.ignition event) would slow the engine speed but be less abrupt and lessnoticeable audibly to the user.

A user interface 165 may be provided so that the user is able to controlthe desired speed (e.g., expected or targeted speed) of the engine 105.This user interface 165 could be an analog input such as a voltagedivider, a fixed resistor, a variable resister (e.g., a potentiometer orsliding variable resistor). In some embodiments where the engine wasused to power a wheel drive train (e.g., on a riding or walk behind lawnmower or snow thrower) a throttle input (e.g., a gas pedal or lever) maybe moved to adjust the analog input and therefore adjust the desiredspeed of the engine. If the engine is used to power a generator, adiscreet two-position analog input could be used to switch the outputfrequency of the electricity provided by the generator between the 60 Hzelectricity used in the United States and Canada, and the 50 Hzelectricity used elsewhere in the rest of the world (e.g., Europe andAsia). Other discreet control modes, for example, could include a quietoperating mode versus a power operating mode. The quiet operating modemay be configured so that the engine runs at a relatively low speed(e.g., 2,400 rpm) versus the power mode which runs at a relatively highrpm (e.g., 3,000 rpm). In some embodiments, the user interface iswireless RF, infrared IR, and LED or light pulse interface or capacitivesensing interface (e.g., a touchscreen). In some embodiments the userinterface 165 includes a second microcontroller. For example, a touchscreen or other interface device could provide inputs to a secondcontroller which provide a variable voltage output to the controlleroperating the electronic governor system. In some embodiments, the userinterface 165 provides a digital input.

Initial performance characteristics of the engine governor system 100can also be varied (e.g., more or less aggressive engine speed errorcorrection. These characteristic settings could be preset when thesystem or engine is assembled (e.g., by setting a specific resistance orvoltage value). For example one setting could be used with relativelylow inertia equipment driven by the engine (e.g., the pump of a pressurewasher) and a second setting could be used with relatively high inertiaequipment driven by the engine (e.g., the blade of a lawn mower). Thisprovides the controller 155 with some initial performancecharacteristics (e.g., the relative inertia of the equipment beingdriven) before it has even had a chance to start adapting the controlparameters based on the actual use of the engine. For example, 1000-4000rpm could be selected with input resistances of 100-400 ohms and withinput resistances of 1100-1400 ohms with settings of 100-400 ohmsproviding moderately aggressive performance for relative low inertiaapplications and 1100-1400 ohms providing more aggressive performancefor relatively high inertia applications. Additionally, there could alsobe more than two performance characteristics settings (e.g., lowinertia, moderately low inertia, moderate inertia, moderately highinertia, high inertia, etc.) that could be selected based on engine type(e.g., size, number of cylinders, rated horsepower, rated torque) andequipment to be driven by the engine. Alternatively, the performancecharacteristic settings could be tied to the voltages that will be readby the controller 155.

A current sensor 175 may be included to monitor the current draw on themotor 115. For example, a shunt resistor may be used to measure thismotor current. The current sensor 175 is used to detect potentialfailures in the electronic governor system 100 and shut down the engine105 (e.g., stop the engine) in response to detecting such a failure. Forexample, a detected current above a high current threshold couldindicate a jam, obstruction, the end of travel, a motor short, or someother situation in which the motor 115, the transmission 120, thethrottle plate 125, the throttle lever 130, the linkage 135, or othermovable component is unable to move (e.g., rotate, translate, etc.) asdesired. When the current sensor 175 detects a current below a lowcurrent threshold this could indicate a broken wire or some other lossof electrical communication between the components of the electronicgovernor system 100. Both a high current above the high threshold and alow current below the low threshold may be indicative of situations inwhich the engine 105 should be stopped or shut down to prevent possibledamage to the engine. Engine shutdown module 230 is configured to shutdown, stop, turn off, or deactivate the engine in response to anappropriate input (e.g., release of a safety interlock, like when thebail of a walk-behind lawn mower is released, movement of an on/offswitch to the off position, etc.). Engine shutdown module 230 mayreceive an input from the current sensor 172 and shut off the engine inresponse to low current or high current as described above.

In some embodiments, the engine speed sensor 160 detects the enginespeed using an ignition signal from the ignition system 180. Forexample, the positive sparks or pulses from the ignition system could becounted and used to determine the engine speed. This method ofdetermining engine speed provides an additional advantage when shortingthe negative pulses or sparks with the rev limiter 185. The engine speeddetection, which is determined from the positive pulses, is not lostwhen slowing down the engine 105 with the rev limiter 185 by shortingthe negative pulses or sparks. In other embodiments, other appropriateengine speed sensors are utilized.

The electronic governor systems described herein are able to adjust theoperating speed of the engine in response to an input from a loadsensing system. Combining a load sensing system with the electronicgovernor systems allows the operating speed of the engine to beoptimized for various load conditions. For example, an engine includingan electronic governor system and a load sensing system as describedherein could operate in one of two modes: a no load or low load mode(e.g., when the blade of a lawn mower is not cutting any grass) wherethe engine operates at an idle or relatively low speed and a high loadmode (e.g., when the blade of the lawn mower is cutting grass) where theengine operates at an high operating or relatively high speed. Morecomplex systems allow for additional modes of operation for example amoderate load mode (e.g., when the blade of the lawn mower is cuttinggrass that is thinner than that being cut in the high load mode) wherethe engine operates at a speed between the idle speed and the highoperating speed. The engine speed could also vary continuously with loador approximately continuously with load (e.g., with a step-function orother appropriate curve fit). For example, the engine speed could becontrolled to always fit within a band or window defined by a highengine speed curve and a low engine speed curve and operate in a mannersimilar to a continuously variable transmission.

The load sensing system makes use of the principle of rotational motionthat the sum of the torques for the system equals zero. The sum of thetorques is equal to inertia times the change in angular velocity asshown in the equation below. The Torque_(Produced) is the torqueproduced from combustion by the engine and the Torque_(Load/Losses) isthe torque produced from the load on the engine (e.g., mower blade,pressure washer pump, drive system, etc.) and any losses within theengine (e.g., friction, gas compression, vacuum, etc.)J{umlaut over (θ)}=Torque_(Produced)−Torque_(Load/Losses)

In a first load sensing system for a single cylinder four-cycle engine,the load can be estimated by comparing the rotational speed of theengine for two consecutive engine revolutions. A “fast” revolutionoccurs during the expansion and exhaust cycles of the engine. A “slow”revolution occurs during the intake and compression cycles of theengine. The difference in revolution speed (e.g., in revolutions perminute (“RPM”)) is a function of the Torque_(Load/Losses) and inertia.When the inertia is known (e.g., the inertia of a specific end use ofthe engine, for example for a specific lawn mower, pressure washer,tractor, or other piece of outdoor power equipment), then the differencein revolution speed from the fast revolution to the slow revolution(e.g., RPM of the fast revolution minus the RPM of the slow revolution)is a function of the Torque_(Load/Losses). By calculating thisdifference, the load sensing system can accurately estimate the load onthe engine. The load can then be used as an input to the electronicgoverning system to control the speed of the engine.

In a second load sensing system for a single cylinder four-cycle engine,the load can be estimated by comparing the rotational speed of theengine for each of the four cycles. The sum of the torques for each ofthe four cycles (expansion, compression, intake, and compression) can becalculated according to the equation shown below.J{umlaut over (θ)}=Torque_(Produced)−Torque_(Loss)−Torque_(Load)

Using four versions of this equation, one for each cycle, with theinertia remaining constant for all four equations, the load sensingsystem is able to determine the load based on the measured change inengine speed from one cycle to the next because each of the fourequations is left with only one unknown (four equations with fourunknowns are solvable). For the expansion cycle, Torque_(Loss) isnegligible and can be assumed to be zero. For the exhaust cycle,Torque_(Produced) and Torque_(Loss) are negligible and can be assumed tobe zero. For the intake cycle, Torque_(Produced) and Torque_(Loss) arenegligible and can be assumed to be zero. For the compression cycle,Torque_(Produced) is negligible and can be assumed to be zero.

The combustion process can vary from combustion cycle. The combustionprocess regularly experiences “bumps” or “pops” due to many possiblefactors including fuel quality, air availability, variations in thefuel-air ration, etc. Either of the two load sensing systems describedabove can reduce the impact of these combustion process variations,which may result in variations of the engine speed, which is the inputsto the calculations used to determine the load for both systems, byusing a running average and/or a standard deviation of the engine speedmeasurements.

The average load value can be calculated using the equation below. “A”is a factor used to weigh the average load value. The value of A may beselected based on the intended end use of the engine (e.g., lawn mower,pressure washer, tractor, or other piece of outdoor power equipment) andthe desired engine performance for that engine. As the value of Aincreases, the average load value becomes smoother, but it delaysresponse time for true changes in load, rather than momentary chancesdue to combustion variations.

${{{Avg}.\mspace{14mu}{Load}}\mspace{14mu}{Value}} = \frac{\left( {{{{Avg}.\mspace{14mu}{Load}}\mspace{14mu}{Value}*A} + {{New}\mspace{14mu}{Load}\mspace{14mu}{Value}}} \right)}{A + 1}$

The average load value can be used as the trigger to change betweenoperating modes of the electronic governing system. For example for thetwo operating mode electronic governing system discussed above, the noload operating mode can be triggered when the average load value is ator below a predetermined threshold value and the high load operatingmode can be triggered when the average load value is at or above apredetermined threshold value. To avoid hunting or hysteresis betweenthe two modes, the predetermined threshold values can be different forthe no load operating mode and the high load operating mode. Forexample, the no load threshold value could be an average load value of15 and the high load threshold value could be 20, providing a windowbetween 15 and 20 where mode hunting is avoided. Alternatively apercentage change threshold (e.g., 20%) in average load value could beused as the trigger to change between operating modes of the electronicgoverning system. The threshold values, whether absolute or apercentage, can be tied to specific engine sizes and end products.Another way to avoid mode hunting is to include a minimum predeterminedtime period between operating mode changes. For example, each operatingmode could be required to run for at least 5 seconds before be able toswitch based on the current average load value. A standard deviation ofthe load value could be used in similar manners on its own or incombination with the average load value to provide a trigger to changebetween operating modes of the electronic governing system. The standarddeviation of the measured engine speed may also be used to distinguishbetween an actual change in engine speed (e.g., due to an increased ordecreased load on the engine) and intermittent variations in enginespeed due to combustion irregularities. Measured engine speed includesexpected variations on a per-cycle basis. The expansion (combustion,power) cycle has a faster engine speed than the intake, compression, andexhaust cycles. The standard deviation accounts for the expectedvariations on a per-cycle basis so that only engine speed changes inexcess of the standard deviation, or in excess of the standard deviationmodified by an error factor (e.g., multiplied or added to the standarddeviation), are used to trigger a change in throttle plate position bythe engine governing system.

Both load sensing systems make use of an appropriate controller toimplement the control schemes discussed above and of an appropriateengine speed sensor to detect the engine speed for use as an input asdiscussed above. Possible engine speed sensors include a magnetic fieldsensor (e.g., a Hall Effect sensor or reed switch) in combination with amagnet on the flywheel. The magnet on the flywheel could be the sameused to generate the spark for the ignition system, but could also be aseparate second magnet. Both load sensing systems could also include anoperating mode input to provide a verification that the detected changein load based on the engine speed calculations as an intended change inload based on the user's intended operating mode. For example, a tiltsensor could indicate when the front wheels of a walk behind lawn mowerare lifted off the ground, thereby confirming a reduced load. A switchon the bail of walk behind lawn mower could indicate when the operatorengages the drive system. A vacuum sensor could detect changes in enginevacuum as a redundant check on load changes.

A user-actuated switch could also be used as a feedforward input to theload sensing system. For example, a switch actuated by a user operatedlever (e.g., the bail of a walk-behind mower, the trigger of a pressurewasher spray gun, a control lever of a snowthrower, a power takeoffengage switch on a riding tractor, etc.) would indicate an expectedengine load to the load sensing system (e.g., operation of the tooldriven by the engine, a load on the tool driven by the engine,engagement of a drive train, etc.). The load sensing system could usethis feedforward input to override or supplement the load outputprovided by the load sensing system.

The same controller or separate controllers can be used to implement thecontrols schemes used by the electronic governor system and by the loadsensing system. For example, as shown in FIG. 2, the controller 155could be used to control both the electronic governor system 100 and aload sensing system as described above via a load sensing module 235configured to implement a load sensing system as described herein. Theengine speed sensor 160 could be used to provide the necessary enginespeed inputs to the load sensing module 235 to implement the loadsensing system.

The construction and arrangement of the apparatus, systems and methodsas shown in the various exemplary embodiments are illustrative only.Although only a few embodiments have been described in detail in thisdisclosure, many modifications are possible (e.g., variations in sizes,dimensions, structures, shapes and proportions of the various elements,values of parameters, mounting arrangements, use of materials, colors,orientations, etc.). For example, some elements shown as integrallyformed may be constructed from multiple parts or elements, the positionof elements may be reversed or otherwise varied and the nature or numberof discrete elements or positions may be altered or varied. Accordingly,all such modifications are intended to be included within the scope ofthe present disclosure. The order or sequence of any process or methodsteps may be varied or re-sequenced according to alternativeembodiments. Other substitutions, modifications, changes, and omissionsmay be made in the design, operating conditions and arrangement of theexemplary embodiments without departing from the scope of the presentdisclosure.

The present disclosure contemplates methods, systems and programproducts on any machine-readable media for accomplishing variousoperations. The embodiments of the present disclosure may be implementedusing existing computer processors, or by a special purpose computerprocessor for an appropriate system, incorporated for this or anotherpurpose, or by a hardwired system. Embodiments within the scope of thepresent disclosure include program products comprising machine-readablemedia for carrying or having machine-executable instructions or datastructures stored thereon. Such machine-readable media can be anyavailable media that can be accessed by a general purpose or specialpurpose computer or other machine with a processor. By way of example,such machine-readable media can comprise RAM, ROM, EPROM, EEPROM, CD-ROMor other optical disk storage, magnetic disk storage or other magneticstorage devices, or any other medium which can be used to carry or storedesired program code in the form of machine-executable instructions ordata structures and which can be accessed by a general purpose orspecial purpose computer or other machine with a processor. Wheninformation is transferred or provided over a network or anothercommunications connection (either hardwired, wireless, or a combinationof hardwired or wireless) to a machine, the machine properly views theconnection as a machine-readable medium. Thus, any such connection isproperly termed a machine-readable medium. Combinations of the above arealso included within the scope of machine-readable media.Machine-executable instructions include, for example, instructions anddata which cause a general purpose computer, special purpose computer,or special purpose processing machines to perform a certain function orgroup of functions.

Although the figures may show or the description may provide a specificorder of method steps, the order of the steps may differ from what isdepicted. Also two or more steps may be performed concurrently or withpartial concurrence. Such variation will depend on various factors,including software and hardware systems chosen and on designer choice.All such variations are within the scope of the disclosure. Likewise,software implementations could be accomplished with standard programmingtechniques with rule based logic and other logic to accomplish thevarious connection steps, processing steps, comparison steps anddecision steps.

What is claimed is:
 1. An electronic governor system, comprising: amotor; a transmission coupled to the motor; a throttle plate coupled tothe transmission, the throttle plate movable to a plurality of positionsbetween closed and wide-open; wherein power is supplied to the motor tomove the throttle plate to a desired position; and wherein power is notsupplied to the motor to maintain the throttle plate in the desiredposition.
 2. The electronic governor system of claim 1, a reductionratio of the transmission is greater than or equal to 40:1.
 3. Theelectronic governor system of claim 1, further comprising: an ellipticalgear set coupling the transmission to the throttle plate, the ellipticalgear set including a driven elliptical gear coupled to the transmissionand a driving elliptical gear coupled to the throttle plate; wherein,when the throttle plate is near the wide open position, a major radiusof the driving elliptical gear engages a minor radius of the drivenelliptical gear; and wherein, when the throttle plate is near the closedposition, a minor radius of the driving elliptical gear engages a majorradius of the driven elliptical gear.
 4. The electronic governor systemof claim 1, further comprising: an ignition system configured to produceexcess energy; and an energy storage device configured to store theexcess energy and to power the motor with the stored excess energy. 5.The electronic governor system of claim 4, wherein the excess energycomprises at least one positive spark.
 6. The electronic governor systemof claim 1, further comprising: an engine speed sensor; and a controllerincluding a feedback control module and an adaptive control module;wherein the feedback control module is configured to: determine anengine speed error based on a comparison of a current engine speed inputsignal from the engine speed sensor and a desired engine speed; andprovide an engine speed output signal to the motor to control theposition of the throttle plate to correct the engine speed error,wherein the engine speed output signal is determined by a controlalgorithm using the engine speed error as an input; wherein the adaptivecontrol module is configured to: determine an expected engine speederror correction based on the engine speed output signal provided by thefeedback control module; determine an actual engine speed errorcorrection based on a current engine speed input signal from the enginespeed sensor and a previous engine speed input signal from the enginespeed sensor; determine a correction error based on the expected enginespeed error correction and the actual engine speed correction; andadjust a parameter of the control algorithm of the feedback controlmodule when the correction error is within a predetermined range oroutside of a predetermined range.
 7. The electronic governor system ofclaim 6, wherein the feedback control module utilizes aproportional-integral-derivative control algorithm to provide the enginespeed output signal and the parameter adjusted by the adaptive controlmodule is at least one of a proportional parameter, an integralparameter, and a derivative parameter.
 8. The electronic governor systemof claim 7, wherein the proportional-integral-derivative controlalgorithm utilizes a plurality of parameter sets, each parameter setincluding a proportional parameter, an integral parameter, and aderivative parameter, and wherein the feedback control module isconfigured to utilize a specific parameter set based on the position ofthe throttle plate.
 9. The electronic governor system of claim 8,wherein a first parameter set is utilized by theproportional-integral-derivative control algorithm when the throttleplate is near the closed position and a second parameter set is utilizedby the proportional-integral-derivative control algorithm when thethrottle plate is near the wide-open position.
 10. The electronicgovernor system of claim 8, further comprising a temperature sensorconfigured to detect a temperature, wherein a first parameter set isutilized by the proportional-integral-derivative control algorithm whenthe detected temperature is below a threshold and a second parameter setis utilized by the proportional-integral-derivative control algorithmwhen the detected temperature is above the threshold.
 11. The electronicgovernor system of claim 6, wherein the feedback control module utilizesa fuzzy logic control algorithm to provide the engine speed outputsignal and the parameter adjusted by the adaptive control module is atleast one parameter of at least one rule of the fuzzy logic controlalgorithm.
 12. The electronic governor system of claim 11, furthercomprising a temperature sensor configured to detect a temperature,wherein the detected temperature is an input to the fuzzy logic controlalgorithm.
 13. The electronic governor system of claim 6, furthercomprising an ignition system, wherein excess energy from the ignitionsystem is used to power the motor.
 14. The electronic governor system ofclaim 6, wherein the adaptive control module is configured to adjust aparameter of the feedback control module such that a subsequent enginespeed output signal is more aggressive when the expected engine speederror correction is less than the actual engine speed correction. 15.The electronic governor system of claim 6, wherein the adaptive controlmodule is configured to adjust a parameter of the feedback controlmodule such that a subsequent engine speed output signal is lessaggressive when the expected engine speed error correction is greaterthan the actual engine speed correction.